Dynamic optimization of overlap-and-add length

ABSTRACT

A method of performing overlap-and-add length for zero-padded suffixes. The method includes derotating received information symbol samples. The derotated received information symbol samples include a first set of derotated received information symbol samples and a second set of derotated received information symbol samples. The first set of derotated received information symbol samples are stored in a buffer. The second set of derotated received information symbol samples are provided to a received sample processing unit. The received zero-padded suffix samples are deroted. Based upon an overlap-and-add length, at least a fraction of the derotated received zero-padded suffix samples is added with at least a fraction of the first set of derotated received information symbol samples to produce multiple summed samples. The multiple summed samples is provided to the received sample processing unit.

CROSS REFERENCE TO RELATED APPLICATIONS

This Application is a Divisional of and claims priority under 35 U.S.C. §121 to U.S. application Ser. No. 11/818,099 filed on Jun. 13, 2007 now U.S. Pat. No. 7,826,572.

BACKGROUND INFORMATION

In order for electronic devices to communicate, a wireless or wired protocol (i.e., standard) defines hardware and software parameters that enable the devices to send, receive, and interpret data. Frequency division multiplexing or frequency division modulation (FDM) is a technology that transmits multiple signals simultaneously over a single transmission path, such as a cable or wireless system. Each signal travels within its own unique frequency range (carrier), which is modulated by data (e.g., text, voice, video, etc.).

Orthogonal FDM (OFDM) distributes the data over a large number of carriers that are spaced apart at precise frequencies. To mitigate multi-path energy and to enable a transmitter and receiver to switch between different frequency bands some wired and wireless protocols define a guard interval that is placed before transmitted information symbols as a prefix. Other protocols define a guard interval that is placed after transmitted information symbols as a suffix (e.g., a zero-padded suffix or “ZPS”). In either case, the guard interval reduces interference between information symbols by providing time for multi-path reflections to attenuate.

FIG. 1 a illustrates zero padded suffix operations at a transmitter and receiver. When a ZPS is used (e.g., in a Multi-Band Orthogonal Frequency Division Multiplexing (OFDM) system), a receiving device may use an “overlap-and-add” operation to add samples of the ZPS to samples of the symbol preceding the ZPS. For example, the overlap-and-add operation may combine the “N” samples of the ZPS with the first N samples of the symbol preceding the ZPS. The overlap-and-add operation may result in too much noise being added to the symbol.

There are a variety of techniques for representing noise at a receiver. FIG. 1 b illustrates an I, Q plane for a quaternary phase shift key modulation (QPSK) scheme which has a constellation of four ideal possible symbols S_(o), S₁, S₂, and S₃ and received signal samples ‘x’ that are not aligned with the ideal possible symbols. The ‘x's’ next to each of the ideal symbols illustrate the common situation that occurs at a receiver that receives a QPSK signal that has passed through a noisy channel. The received modulated signal samples are not aligned with the ideal constellation points. For example, received symbol 104 is not aligned with ideal constellation symbol S₃ 102. The error distance 106 between the vector 108 to received symbol 104 and the vector 109 to ideal symbol S₃ is representative of the noise that led to the misalignment. An error vector magnitude (EVM) metric is defined as the square root of the mean of the square of the error distances for received symbol samples around each of the ideal constellation symbols. The EVM is calculated per frame of received symbols or some other period of time. The EVM may be expressed in dB or as % RMS (root-mean-square) of the signal strength. EVM can be calculated for modulation schemes other than QPSK.

Typically, the greater the noise that is affecting modulated signals the greater the error distance between received signal samples and the ideal symbol with which they are associated. The greater the error distance the more difficult it becomes to map received signal samples to their associated ideal symbol and may prevent communication from occurring in some instances. Consequently, the problem of relatively too much noise being added during overlap-and-add operation is a significant and very substantial issue that needs addressing with solutions that overcome the deficiencies of the prior art.

BRIEF DESCRIPTION OF THE DRAWINGS

The invention is illustrated by way of example, and not limitation, in the figures of the accompanying drawings in which like references denote similar elements, and in which:

FIG. 1 a illustrates zero padded suffix operations at a transmitter and receiver;

FIG. 1 b illustrates an I, Q plane for a quaternary phase shift key modulation (QPSK) scheme which has a constellation of four ideal possible symbols S_(o), S_(1i), S₂, and S₃ and received signal samples ‘x’ that are not aligned with the ideal possible symbols;

FIG. 2 a illustrates a system in accordance with an embodiment of the disclosure;

FIG. 2 b illustrates a packet and its component elements according to an embodiment of the invention;

FIG. 3 a illustrates a block diagram of a receiver in accordance with an embodiment of the invention;

FIG. 3 b illustrates a block diagram of a receiver according to an alternative embodiment of the invention;

FIG. 3 c illustrates a block diagram of a receiver according to an alternative embodiment of the invention;

FIG. 3 d illustrates a block diagram of a receiver according to an alternative embodiment of the invention;

FIG. 4 a illustrates a block diagram of OLA logic of FIG. 3 a in accordance with an embodiment of the invention;

FIG. 4 b illustrates a block diagram of OLA logic of FIG. 3 a in accordance with an alternative embodiment of the invention;

FIG. 4 c illustrates a block diagram of OLA logic of FIG. 3 a in accordance with yet another alternative embodiment of the invention;

FIG. 5 illustrates an SNR estimate generator based on an error vector magnitude metric;

FIG. 6 illustrates an SNR estimate generator according to an alternative embodiment of the invention;

FIG. 7 illustrates a channel impulse magnitude response estimate some of whose coefficients exceed a threshold according to an embodiment of the invention;

FIG. 8 a illustrates a process for setting the overlap-and-add length according to an embodiment of the invention;

FIG. 8 b illustrates in greater detail the effective channel length estimation operation of FIG. 8 a in accordance with an embodiment of the invention;

FIG. 8 c illustrates a process for setting a threshold value used to determine effective channel length according to an embodiment of the invention.

DETAILED DESCRIPTION

According to the invention, methods and apparatus for dynamic optimization of the overlap-and-add length are described. In the following description, for purposes of explanation, numerous specific details are set forth in order to provide a thorough understanding of embodiments according to the invention. It will be evident, however, to one of ordinary skill in the art that the invention may be practiced in a variety of contexts including orthogonal frequency division multiplexing systems without these specific details. In other instances, well-known operations, steps, functions and elements are not shown in order to avoid obscuring the description.

Parts of the description will be presented using terminology commonly employed by those skilled in the art to convey the substance of their work to others skilled in the art, such as overlap-and-add, zero-padded suffix, fast Fourier transform (FFT), channel impulse response estimate, frequency equalization, signal-to-noise ratio (SNR) and so forth. Various operations will be described as multiple discrete steps performed in turn in a manner that is most helpful in understanding the embodiments according to the invention. However, the order of description should not be construed as to imply that these operations are necessarily performed in the order that they are presented, or even order dependent. Repeated usage of the phrases “in an embodiment,” “an alternative embodiment,” or an “alternate embodiment” does not necessarily refer to the same embodiment, although it may. Additionally, one of ordinary skill in the art would appreciate that a graphical description of an apparatus in the figures of the drawings interchangeably represents either an apparatus or a method.

Embodiments of the present disclosure illustrate methods and apparatus that reduce the amount of noise that is introduced to samples of a received signal when an overlap-and-add operation is used with a zero-padded suffix (ZPS). Embodiments of the present disclosure illustrate methods and apparatus that reduce the latency in providing received signal samples to FFT logic. Embodiments of the present disclosure illustrate methods and apparatus that reduce the amount of noise that is introduced to samples of a received signal when an overlap-and-add operation is used with a zero-padded suffix (ZPS) and that reduce the latency in providing received signal samples to FFT logic. This description incorporates herein by reference U.S. patent application Ser. No. 11/331,463 titled “Methods And Systems For Performing An Overlap-And-Add Operation,” filed on Jan. 13, 2006. The immediately aforementioned application is referred to herein as the '463 application. The '463 application also discloses embodiments in which latency in providing received signal samples to FFT logic is reduced. One of ordinary skill in the art would appreciate how the teachings of the '463 application would be combined with the present disclosure in yet other alternative embodiments of the invention in order to also achieve noise and latency reduction.

Electronic devices that communicate wirelessly (or via a wired connection) implement a variety of techniques to prepare, send, receive, and recover data. For example, data preparation techniques may include data scrambling, error correction coding, interleaving, data packet formatting, and/or other techniques. The data to be transmitted is converted into blocks of data (i.e., bits) transmitted as information symbols. Each information symbol is associated with a constellation of complex amplitudes. If data communication is wireless, one or more antennas “pick up” the wireless signal, after which data is recovered by sampling the received signal and decoding each information symbol. To recover data, a receiving device may implement techniques such as signal amplification, digitization, sample rate conversion, equalization, demodulation, de-interleaving, de-coding, and/or de-scrambling.

In some communication systems, such as a Multi-Band Orthogonal Frequency Division Multiplexing (MB-OFDM) system, a zero-padded suffix (ZPS) follows each information symbol. Embodiments of the disclosure illustrate methods and apparatus that reduce the amount of noise that is introduced to samples when an overlap-and-add operation is used with a ZPS. In at least some embodiments, the noise reduction is achieved by adding less than all the ZPS samples to the corresponding first samples of the symbol being received. For example, in some embodiments, if the ZPS corresponds to “N” samples and the information symbol corresponds to M samples, then m ZPS samples are added to the first m samples of the information symbol preceding the ZPS, where m<N. The remaining N-m samples of the ZPS are ignored. The M samples of the information symbol—whose first m samples have now had the first m ZPS samples added to them—are provided to the receiver's FFT logic. In alternative embodiments, some of a symbol's M samples are provided to the receiver's FFT logic before the m ZPS samples are added to the first m samples of the symbol. Several such alternative embodiments which minimize noise and latency in providing samples to the receiver's FFT logic are described herein. One of ordinary skill in the art would understand how, in yet other alternative embodiments, the teachings in the '463 application would be combined with the present disclosure so that latency and noise are also minimized on a per OFDM packet basis.

FIG. 2 a illustrates a system 110 in accordance with an embodiment of the disclosure. As shown in FIG. 2 a, system 110 comprises devices 111 a and 111 b. Device 111 a includes a transceiver 112 a having a data link layer 114 a and a PHY layer 116 a. Similarly, device 111 b includes a transceiver 112 b having a data link layer 114 b and a PHY layer 116 b. In at least some embodiments, the data link layers and the PHY layers function according to a standardized communication protocol. For clarity, only the components of device 111 a are described in greater detail. However, the same discussion would apply to the components of device 111 b.

In order for device 111 a to communicate wirelessly, the PHY layer 116 a and the data link layer 114 a perform several functions such as preparing, transmitting, receiving, and decoding wireless signals. In some embodiments, the PHY layer 116 a implements a physical layer convergence procedure (PLCP) sub-layer, a physical medium dependent (PMD) sub-layer and dynamic overlap-and-add logic 118 a.

The PLCP sub-layer of device 111 a enables carrier sense and clear channel assessment (CCA) signals to be provided to the data link layer 114 a (indicating when the PHY layer 116 a is in use). The PMD sub-layer of the PHY layer 116 a provides encoding, decoding, modulation, and/or demodulation of information symbols for device 111 a. In some embodiments, the PMD sub-layer of the PHY layer 116 a permits device 111 a to implement modulation techniques such as multi-band OFDM. The PMD sub-layer also may provide functions such as analog-to-digital and/or digital-to-analog data conversion.

As shown, the data link layer 114 a implements a logical link control (LLC) and a medium access control (MAC). During transmission of data, the LLC assembles data frames with address and cyclic redundancy check (CRC) fields. During reception of data, the LLC disassembles data frames, performs address recognition, and performs CRC validation. The MAC functions, at least in part, to coordinate transmission of data between the electronic device 111 a and other devices (e.g., device 111 b).

The dynamic overlap-and-add logic 118 a shown in FIG. 2 a enables dynamic overlap-and-add operations to be performed, on the fly for each received OFDM packet, using the overlap-and-add (OLA) length (OLAL) that provides best performance. For example, in embodiments that implement multi-band OFDM, overlap-and-add operations are performed (when data is received) to overlap-and-add less than all of the samples of a zero-padded suffix (ZPS) to corresponding samples of an information symbol preceding the ZPS.

FIG. 3 a illustrates a block diagram of a receiver in accordance with an embodiment of the invention. In an embodiment, receiver 300 is part of PHY layer 116 a previously described. As indicated, in an embodiment, PHY layer 116 a is compatible with a MB-OFDM physical layer specification. However, receiver 300, its constituent units, and other units or processes described herein are not limited to a particular protocol and may be part of any wired or wireless system that receives information symbols followed by a ZPS. The ZPS provides a mechanism to mitigate multi-path energy and enables a transmitter and receiver to switch between different frequency bands.

As shown in FIG. 3 a, receiver 300 includes dynamic overlap-and-add (OLA) logic 302 that receives samples of an incoming signal. OLA logic 302 also receives a channel impulse response (CIR) estimate and a signal-to-noise-ratio (SNR) estimate. In an embodiment, based upon the CIR estimate and SNR estimate, OLA logic 302 dynamically performs overlap-and-add operations and provides overlapped-and-added (modified) samples and non-modified samples to FFT logic 304. As described in greater detail, OLA logic 302 also performs overlap-and-add operations when the CIR estimate, SNR estimate, or both are missing.

One of ordinary skill in the art would appreciate that the overlap-and-add operations are part of a convolution process that uses the extra samples of the ZPS to allow multiplication in the frequency domain to be used to form the desired output. As indicated earlier, in some embodiments, in accordance with the disclosure in the '463 application, FFT logic 304 receives at least some unmodified samples of the information symbol preceding a ZPS before any symbol samples are added to the ZPS samples.

FFT logic 304 extracts frequency spectrum data from the incoming signal samples and outputs the frequency spectrum data to channel estimator 306. Channel estimator 306 determines the channel impulse response which is used by frequency equalizer 308 to remove the frequency shaping caused by the communication channel. Frequency equalizer 308 outputs “equalized” frequency spectrum data to constellation de-mapper 310. The output of the frequency equalizer 308 is received by the constellation de-mapper 310, which converts the equalized frequency spectrum data to information symbols that can be decoded by a decoder.

FIG. 4 a illustrates a block diagram of OLA logic 302 of FIG. 3 a in accordance with an embodiment of the invention. As shown in FIG. 4 a, OLA logic 302 includes dynamic OLA control (OLAC) logic 303 a that accepts an SNR estimate and a CIR estimate. Based upon the SNR and CIR estimates, OLAC 303 a sets the OLA length, OLAL, that is used in the overlap-and-add operation of adder 303 d.

OLA logic 302 includes numerically controlled oscillator (NCO) 303 b which receives signal samples and a frequency offset indication from a tracking unit (not shown). Based upon the frequency offset indication NCO 303 b performs complex multiplication on the received signal samples in order to remove the phase offset that results due to the frequency offset between the transmitter oscillator (not shown) and receiver oscillator (not shown). OLA logic 302 also includes buffer 303 c which receives phase adjusted signal samples of substantially the beginning of an information symbol from NCO 303 b and stores them temporarily until the OLA operation of adder 303 d starts. In an embodiment, buffer 303 c stores N samples at a time, where N, in an embodiment is 32. The number of samples, N, stored by buffer 303 c is an implementation detail that can vary depending upon the embodiment, as one of ordinary skill in the art would readily appreciate.

The first OLAL samples of an information symbol that are produced by NCO 303 b are stored in buffer 303 c and are not provided to adder 303 d until the OLA operation starts. The next N-OLAL samples of the information symbol that are produced by NCO 303 b are both stored in buffer 303 c and are passed to FFT logic 304 via multiplexer (mux) 303 e. OLAC 303 a instructs mux 303 e to pass the N-OLAL samples to FFT logic 304.

As additional samples beyond the first N samples arrive, NCO 303 b performs the necessary phase adjustment on them and provides them to multiplexer (mux) 303 e. OLAC 303 a instructs multiplexer 303 e to pass an additional 128-N adjusted samples from NCO 303 b to FFT logic 304 such that a total of 128-OLAL adjusted samples will have been passed to FFT logic 304, where OLAL (OLAL≦N) is the number of stored samples that adder 303 d adds to an equivalent number of zero-padded suffix samples. In an embodiment, the number, OLAL (or m), of stored samples that are added to an equal number, OLAL, of zero-padded suffix samples is based either upon the SNR and CIR estimates, if any received, by OLAC 303 a or a default value, DEFVALM. A process for setting the value of OLAL is described in greater detail elsewhere herein.

After 128 symbol samples have been adjusted by NCO 303 b, zero-padded suffix samples arrive at NCO 303 b and are phased adjusted as well. As the first OLAL zero-padded suffix adjusted samples emerge from NCO 303 b, OLAC 303 a instructs buffer 303 c to release the buffered samples to adder 303 d. Adder 303 d adds the released samples with the corresponding OLAL adjusted zero-padded suffix samples and provides the sum to mux 303 e. OLAC 303 a instructs mux 303 e to pass to FFT logic 304 the output of adder 303 d rather than the output of NCO 303 b.

One of ordinary skill in the art would appreciate that timing offsets in a physical implementation may result in some zero-padded suffix samples being considered information symbol samples and vice versa. Thus, the invention is not limited to embodiments in which timing is perfect and information symbol samples are not mistakenly used as zero-padded suffix samples, or vice versa. The foregoing qualification is applicable to all the embodiments described herein.

FIG. 4 b illustrates a block diagram of OLA logic 302 of FIG. 3 a in accordance with an alternative embodiment of the invention. As shown in FIG. 4 a, OLA logic 302 includes dynamic OLA control (OLAC) logic 305 a that accepts an SNR estimate and a CIR estimate. Based upon the SNR and CIR estimates, OLAC 305 a sets the OLA length, OLAL, that is used in the overlap-and-add operation of adder 305 d.

OLA logic 302 of FIG. 4 b includes numerically controlled oscillator (NCO) 305 b which receives signal samples and a frequency offset indication from a tracking unit (not shown). Based upon the frequency offset indication, NCO 305 b performs complex multiplication on the received signal samples in order to remove the phase offset that results due to the frequency offset between the transmitter oscillator (not shown) and receiver oscillator (not shown). OLA logic 302 also includes buffer 305 c which receives phase-adjusted signal samples from NCO 305 b and stores them temporarily until the OLA operation of adder 305 d starts. Unlike buffer 303 c, buffer 305 c stores OLAL samples at a time, where OLAL, is set by OLAC 305 a based on CIR and SNR estimates or a default value, DEFVALM, and, in an embodiment, varies between 1 and 32. In an embodiment, the OLAL information symbol samples stored in buffer 305 c are the OLAL samples that are output by NCO 305 b at substantially the beginning of the 128 information symbol samples. While OLAL varies between 1 and 32 in an embodiment, the range over which OLAL varies is an implementation detail that can vary depending upon the embodiment, as one of ordinary skill in the art would readily appreciate.

As additional symbol samples beyond the first OLAL samples arrive, NCO 305 b performs the necessary phase adjustment on them and provides them to multiplexer (mux) 305 e. OLAC 305 a instructs multiplexer 305 e to pass 128-OLAL adjusted samples from NCO 305 b to FFT logic 304, where OLAL is the number of buffered samples that adder 305 d adds to an equivalent number of adjusted ZPS samples. The number, OLAL (or m), of adjusted ZPS samples that are added to an equal number, OLAL, of information symbol samples is based either upon the SNR and CIR estimates, if any received, by OLAC 305 a or a default value, DEFVALM. A process for setting the value of OLAL is described in greater detail elsewhere herein. As the last OLAL adjusted information symbol samples emerge from NCO 305 b, OLAC 305 a instructs buffer 305 c to release the buffered samples to adder 305 d. Adder 305 d adds the OLAL released samples with the corresponding OLAL adjusted ZPS samples and provides the sum to mux 305 e. OLAC 305 a instructs mux 305 e to pass to FFT logic 304 the output of adder 305 d rather than the output of NCO 305 b.

FIG. 4 c illustrates a block diagram of OLA logic 302 of FIG. 3 a in accordance with an alternative embodiment of the invention. As shown in FIG. 4 c, OLA logic 302 includes dynamic OLA control (OLAC) logic 307 a that accepts an SNR estimate and a CIR estimate. Based upon the SNR and CIR estimates, OLAC 307 a sets the OLA length, OLAL, that is used in the overlap-and-add operation of adder 307 d. OLA logic 302 of FIG. 4 c allows, as will be apparent from the description herein, FFT logic 304, channel estimator 306 and equalizer 308 to be relatively simple in comparison to the FFT logic 304, channel estimator 306 and equalizer 308 that would work with OLA logic 302 of FIG. 4 a, 4 b.

OLA logic 302 of FIG. 4 c includes numerically controlled oscillator (NCO) 307 b which receives signal samples and a frequency offset indication from a tracking unit (not shown). Based upon the frequency offset indication, NCO 307 b performs complex multiplication on the received signal samples in order to remove the phase offset that results due to the frequency offset between the transmitter oscillator (not shown) and receiver oscillator (not shown). OLA logic 302 also includes buffer 307 c which receives phase-adjusted samples of substantially the beginning of an information symbol from NCO 307 b and stores them temporarily until the OLA operation of adder 307 d starts. Unlike buffer 305 c, buffer 307 c stores N samples at a time, where N, in an embodiment is 32. The number of samples, N, stored by buffer 303 b is an implementation detail that can vary depending upon the embodiment, as one of ordinary skill in the art would readily appreciate.

As additional information symbol samples beyond the first N samples arrive, NCO 307 b performs the necessary phase adjustment on them and provides them to multiplexer (mux) 307 e. OLAC 307 a instructs multiplexer 307 e to pass 128-N phase-adjusted information symbol samples from NCO 307 b to FFT logic 304.

When adjusted zero-padded suffix samples start to emerge from NCO 307 b, OLAC 307 a instructs buffer 307 c to output OLAL adjusted information symbol samples to adder 307 d. Adder 307 d adds the OLAL adjusted information symbol samples from buffer 307 c with a corresponding number of incoming zero-padded suffix samples derotated by NCO 307 b. OLAC 307 a instructs multiplexer 307 e to output these summed OLAL samples to FFT logic 304.

After OLAL buffered information symbol samples have been added to a corresponding number of OLAL adjusted ZPS samples, OLAC 307 a disables one of the inputs of AND gate 307 f and continues to assert the selection line to mux 307 e so that the output of adder 307 d is selected rather than the output of NCO 307 b. Buffer 307 c releases the remaining N-OLAL information symbol samples to adder 307 d which passes them to mux 307 e, and mux 307 e passes them to FFT logic 304.

One of ordinary skill in the art would appreciate that in an alternative embodiment, OLA logic 302 of FIG. 4 c includes a three-input mux rather than a two-input mux such as mux 307 e. In such an alternative embodiment, the third input of the three-input mux accepts the output of buffer 307 c. The other two inputs of the three-input mux are as shown in FIG. 4 c. Instead of OLAC 307 a disabling AND gate 307 f and instructing mux 307 e to select the output of adder 307 d as the last N-OLAL information symbol samples emerge from buffer 307 c, it instructs mux 307 e to select the output of buffer 307 c so that the remaining N-OLAL information samples coming from buffer 307 c (rather than summed samples from adder 307 d) are passed to FFT logic 304.

As indicated earlier, OLA logic 302 of FIG. 4 c allows FFT logic 304, channel estimator 306 and frequency equalizer 308 to be relatively simple because while they are waiting for the OLAL summed samples to emerge from adder 303 d they start processing the (N+1)^(st) information symbol sample through the 128^(th) information symbol sample. In contrast, the variable store operation in OLA logic 302 of FIGS. 4 a, 4 b adds complexity because FFT logic 304, channel estimator 306 and equalizer 308 would receive a variable FFT starting sample number depending upon the value for OLAL that was set by OLAC 303 a or OLAC 305 a. A well-known property of FFTs is that a cyclical shift of samples in the time domain results in a linear phase shift in the frequency domain, and vice versa. Consequently, a variable phase shift as a function of the number of samples stored in the buffer complicates the implementation of FFT logic 304, channel estimator 306 and frequency equalizer 308.

One of ordinary skill in the art would appreciate that in an alternative embodiment for each of OLA logic 302 of FIGS. 4 a, 4 b, and 4 c, SNR and CIR estimates are not used to set the overlap-and-add length, but rather a default value is used,

FIG. 8 a illustrates a process for setting the overlap-and-add length according to an embodiment of the invention. In an embodiment, OLAC 303 a performs process 400. In alternative embodiments, OLAC 305 a or OLAC 307 a performs process 400. In process 400, OLAL is set 402 to a default value, DEFVALM. In an embodiment, DEFVALM is 24 (i.e., 24 samples), but alternative embodiments may use smaller or larger values or even alternate between using smaller or larger values. Continuing with process 400, OLAC 303 a determines 404 whether an SNR estimate is available. When an SNR estimate is available for the packet being received, OLAC 303 a sets 406 OLAL to a value that corresponds to the SNR estimate. In an embodiment, SNR estimates are divided into three categories—High SNR, Medium SNR, and Low SNR—and each of the categories has a one-to-one correspondence with an OLAL value. In an embodiment, High SNR is associated with an OLAL value of 24 samples. Medium SNR is associated with an OLAL value of 16 samples. Low SNR is associated with an OLAL value of 8. OLAC 303 a then determines 408 whether a channel impulse response (CIR) estimate is available. When a CIR estimate is not available, OLAC 303 a uses 416 OLAL as previously set in process 400 to control elements 303 b through 303 f in OLA logic 302 of FIG. 4 a.

When a CIR estimate is available, OLAC 303 a estimates 410 the effective channel length (EffChL). FIG. 8 b illustrates in greater detail the effective channel length estimation operation of FIG. 8 a in accordance with an embodiment of the invention. In an embodiment, OLAC 303 a estimates 411 a the effective channel length by determining the number of coefficients in the CIR estimate with magnitude that exceeds a threshold value that is X % of the largest coefficient magnitude. FIG. 7 illustrates a channel impulse magnitude response estimate some of whose coefficients exceed a threshold according to an embodiment of the invention. OLAC 303 a sets 411 a EffChL to the number of CIR estimate coefficients that exceed the threshold value of X % of the magnitude of the largest coefficient. In an embodiment, X is set to 20, X has other values in alternative embodiments. In an alternative embodiment, X is set according to SNR estimates received by OLAC 303 a.

Continuing with process 400, OLAC 303 a then determines 412 whether EffChL is greater than or equal to an OLA minimum length (OALML) and less than or equal to the present value of OLAL. When EffChL is either not greater than or equal to an OLA minimum length (OALML) or not less than or equal to the present value of OLAL, OLAC 303 a determines 418 whether EffChL is less than or equal to OALML. When EffChL is less than or equal to OALML, OLAC 303 a sets 420 OLAL to OALML.

When OLAC 303 a determines that EffChL is not less than or equal to OALML, OLAC 303 a uses 416 the present value of OLAL (i.e., default value, DEFVALM) in performing the overlap-and-add control related operations described herein in connection with FIG. 4 a.

FIG. 8 c illustrates a process for setting a threshold value used to determine effective channel length according to an embodiment of the invention. In process 401, OLAC 303 a determines 403 a whether an SNR estimate is available for a packet. When an SNR estimate is available for a packet, OLAC 303 a sets 403 b X to a value based on the SNR estimate. A larger value of X is used for low SNR values and vice versa. For low SNR values, in an embodiment, X is greater than 40. For high SNR values, in an embodiment, X is less than 20. In an embodiment, the SNR estimate is determined as part of receiving a packet's preamble and/or physical layer convergence protocol (PLCP) header. FIG. 2 b illustrates a packet and its component elements according to an embodiment of the invention. When an SNR estimate is not available for a packet, OLAC 303 a sets X to a default value. In an embodiment, the default value of X is 20.

CIR estimates and SNR estimates can be made through a variety of techniques. Several techniques are illustrated herein. However, one of ordinary skill in the art would appreciate that the invention is not limited to any particular technique. The immediately foregoing point is emphasized by FIG. 3 a which illustrates OLA logic 302 of receiver 300 as accepting SNR and CIR estimates.

FIG. 3 b illustrates a block diagram of a receiver according to an alternative embodiment of the invention. Receiver 320 includes synch detector 322 which includes a SNR and time domain CIR estimator. In addition to performing packet and frame synchronization when the preamble of a packet is being received (see FIG. 2 b), synch detector 322 applies a matched filter to the synch sequence of the preamble on a per symbol basis to create a per symbol CIR estimate. Matched filters are well known in the art and need not be described in greater detail herein.

In an embodiment, the CIR estimates for several symbols are averaged by synch detector 322, and synch detector 322 provides an average CIR estimate to OLA logic 324 to use as the CIR estimate. In an alternative embodiment, detector 322 provides the per symbol CIR estimate to logic 324 for averaging into a CIR estimate.

Synch detector 322 also generates a SNR estimate which it provides to OLA logic 324. In an embodiment, detector 322 averages the absolute value (or alternatively squared value) of the differences between normalized received samples of similar symbols in the synch sequence. The average of the differences is mapped to an SNR value and detector 322 provides to OLA logic 324 the SNR value as the SNR estimate. The remaining units 324 through 332 of receiver 320 operate in the same manner as their corresponding units described in connection with receiver 300 of FIG. 3 a, and need not be described again.

FIG. 3 c illustrates a block diagram of a receiver according to an alternative embodiment of the invention. Receiver 340 includes dynamic OLA logic 344 that receives a CIR estimate from synch detector 342. Detector 342 generates the CIR estimate(s) as described elsewhere herein and the generation of CIR estimates need not be described again. Dynamic OLA logic 344 also receives an SNR estimate.

As indicated, there are a variety of techniques for producing an SNR estimate and the invention is not limited to any particular technique. FIG. 5 illustrates an SNR estimate generator based on an error vector magnitude metric. In an embodiment, SNR estimate generator 312 receives symbol samples from constellation de-mapper 310. SNR estimate generator 312 determines the error distance between the received symbol samples and their corresponding ideal constellation symbol which is defined by the type of modulation being used. Based upon the error distances, generator 312 determines an error vector magnitude (EVM) metric and maps the EVM metric to an SNR estimate and provides the SNR estimate, depending upon the embodiment under consideration, to one of OLA logic 302, 344, and 354. Some embodiments of receivers 300, 340, and 360, include SNR estimate generator 312.

In an embodiment, SNR estimate generator 312 generates a more accurate SNR estimate by determining the EVM metric for the data portion of a packet (see FIG. 2 b). After generator 312 provides a more accurate SNR estimate to, depending upon the embodiment, OLA logic 302, 344, and 354, logic 302, 344, and 354, depending upon the embodiment, uses the new more accurate SNR estimate in performing a process such as process 400 described in connection with FIG. 8.

FIG. 6 illustrates an SNR estimate generator according to an alternative embodiment of the invention. SNR estimate generator 319 comprises a decoder 314 that receives de-mapped symbols from a constellation de-mapper such de-mapper 310. Decoder 314 decodes the de-mapped symbols and provides the decoded information to PLCP header extractor 316 which disassembles the header of a packet (see FIG. 2 b). Header extractor 316 provides the fields of the header that relate to data rate to data rate and rate decoder 318. In an embodiment, based upon the rate being used, decoder 318 provides an SNR estimate to, depending upon the embodiment, one of OLA logic 302, 344, and 354. When the rate is high, the SNR estimate is high. When the rate is low, the SNR estimate is low, and when the rate is medium the SNR estimate is medium. One ordinary skill in the art would appreciate that the invention is not limited to the classifications low, medium or high and that other classifications and types of mapping may be used.

FIG. 3 d illustrates a receiver according to an alternative embodiment of the invention. Receiver 360 includes a channel estimator 358 that provides a CIR estimate to OLA logic 354. The manner in which channel estimators produce channel estimates is well known in the art and need not be described in greater detail herein. OLA logic 354 also receives an SNR estimate that is generated according to one of the techniques described herein or equivalents known in the art. In an embodiment, logic 354 receives the SNR estimate from synch detector 352 which generates the SNR estimate in accordance with the description provided above in connection with detector 322 of FIG. 3 b. Using the received CIR and SNR estimates, OLA logic 354 performs a process such as process 400. The remaining units 356, 358, 360 and 362 of FIG. 3 d operate in a manner similar to corresponding units 304, 306, 308, and 310 in FIG. 3 a and need not be described in greater detail herein.

Returning to synch detector 322 of FIG. 3 b, in an embodiment, detector 322 produces a CIR estimate through a process of cross-correlation and averaging when the preamble of a packet is being received. With the transmitted preamble sequence represented by x(n), the received sequence of the preamble can be described by the following equation, Eq. 1:

$\begin{matrix} {{r(n)} = {{\sum\limits_{i = 0}^{N - 1}{{x\left( {i - k} \right)}{h(k)}}} + {n(i)}}} & {{Eq}.\mspace{14mu} 1} \end{matrix}$

where n(i) is additive white Gaussian noise (AWGN) with variance Γ², h(k) is the CIR. If the preamble sequence is assumed to have an ideal auto-correlation (it actually only approximates the ideal) as illustrated by Eq. 2

$\begin{matrix} {{\phi_{xx}(m)} = {{\sum\limits_{i = 0}^{N - 1}{{x\left( {i + m} \right)}{x(i)}}} = {\delta(m)}}} & {{Eq}.\mspace{14mu} 2} \end{matrix}$

then the cross-correlation between the transmitted and received signals will be as given by Eq. 3,

$\begin{matrix} {{\phi_{rx}(m)} = {{\sum\limits_{i = 0}^{N - 1}{{r\left( {i + m} \right)}{x(i)}}} = {\hat{h}(m)}}} & {{Eq}.\mspace{14mu} 3} \end{matrix}$

where ĥ(m) is the estimated CIR. This ĥ(m) is estimated on several symbols in the preamble. The results are averaged and provided by detector 322 to OLA logic 324.

In an alternative embodiment, detector 322 generates a CIR estimate by using a least means square (LMS) technique during the channel estimation sequence (see FIG. 2 b). The LMS estimate may be represented by the following two equations, Eqs. 4 and 5, e _(k) =r _(k) −y _(k)  Eq. 4 ĥ _(k+1) =ĥ _(k) +μe _(k) x* _(k)  Eq. 5

where e_(k) is an estimation error, r_(k) is the received signal, y_(k) is the estimated received signal, x_(k) is the channel estimation input sequence, and μ is an adaptive step-size. One of ordinary skill in the art would appreciate that the tracking performance and stability of the LMS estimate is generally dependent on the adaptive step-size, μ, and would be able to select the step-size that would work for a particular implementation of an embodiment according to the invention.

In the preceding specification, the invention has been described with reference to specific exemplary embodiments of the invention. It will, however, be evident to one of ordinary skill in the art that various modifications and changes may be made without departing from the broader spirit and scope of the invention as set forth in the claims that follow. The specification and drawings are accordingly to be regarded in an illustrative rather than restrictive sense and the intention is not to be limited to the details given herein, but rather to be modified within the scope of the appended claims along with their full scope of equivalents. The various elements or components described herein may be combined or integrated in another system or certain features may be omitted, or not implemented. Embodiments can be expressed as—and are not limited to—components, processes, systems, articles of manufacture, compositions of matter, and apparatus with some, all, or a fraction of the features described herein. 

1. A method of performing overlap-and-add operations for signals with zero-padded suffixes, the method comprising: derotating received information symbol samples, the derotated received information symbol samples include a first set of derotated received information symbol samples and a second set of derotated received information symbol samples; storing in a buffer the first set of derotated received information symbol samples; providing the second set of derotated received information symbol samples to a received sample processing unit; derotating received zero-padded suffix samples; based upon an overlap-and-add length, adding at least a fraction of the derotated received zero-padded suffix samples with at least a fraction of the first set of derotated received information symbol samples to produce multiple summed samples; and providing the multiple summed samples to the received sample processing unit.
 2. The method of claim 1, wherein the number of samples in the first set of derotated received information symbol samples that are stored in the buffer depends upon the overlap-and-add length.
 3. The method of claim 2, further comprising determining the overlap-and-add length.
 4. The method of claim 1, further comprising providing at least a second fraction of the first set of derotated received information symbol samples to the received sample processing unit without adding any of the derotated received zero-padded suffix samples.
 5. The method of claim 4, wherein the at least a second fraction of the first set of derotated received information symbol samples is provided to the received sample processing unit before the multiple summed samples are provided.
 6. The method of claim 1, further comprising: summing each of the samples in at least a second fraction of the first set of derotated received information symbol samples with substantially zero to produce a second set of multiple summed samples; and providing the second set of multiple summed samples to the received sample processing unit.
 7. An apparatus for performing overlap-and-add operations for a received signal, the apparatus comprising: a derotating unit that is to derotate received information symbol samples, the derotated received information symbol samples include a first set of derotated received information symbol samples and a second set of derotated received information symbol samples; a buffer coupled to the derotating unit and that is to store the first set of derotated received information symbol samples; wherein the derotating unit is to provide the second set of derotated received information symbol samples to a received sample processing unit and is to derotate received zero-padded suffix samples; an adder coupled to the buffer and the derotating unit; a control logic unit that is to instruct the adder to add, based upon an overlap-and-add length, at least a fraction of the derotated received zero-padded suffix samples with at least a fraction of the first set of derotated received information symbol samples to produce multiple summed samples and provide the multiple summed samples to the received sample processing unit.
 8. The apparatus of claim 7, wherein the number of samples in the first set of derotated received information symbol samples that are stored in the buffer depends upon the overlap-and-add length.
 9. The apparatus of claim 8, wherein the control logic unit is to determine the overlap-and-add length.
 10. The apparatus of claim 7, wherein the derotator unit is to provide at least a second fraction of the first set of derotated received information symbol samples to the received sample processing unit without summing with any of the derotated received zero-padded suffix samples.
 11. The apparatus of claim 10, wherein the at least a second fraction of the first set of derotated received information symbol samples is to be provided to the received sample processing unit before the multiple summed samples are to be provided.
 12. The apparatus of claim 7, wherein the adder is to sum each of the samples in at least a second fraction of the first set of derotated received information symbol samples with substantially zero to produce a second set of multiple summed samples and is to provide the second set of multiple summed samples to the received sample processing unit.
 13. The apparatus of claim 7, further comprising the received sample processing unit, wherein the received sample processing unit includes a fast fourier transform unit coupled to the derotator unit and the adder, and the fast fourier transform unit is to perform a transform on the multiple summed samples and the second set of derotated received information symbol samples.
 14. The apparatus of 13, wherein the received sample processing unit includes frequency equalizer that is coupled to the fast fourier transform unit and that is to perform frequency domain equalization on the multiple summed samples and the second set of derotated received information symbol samples. 